Novel N-hydroxymethyl compounds, compositions containing such compounds and cellulose-containing textile materials treated therewith

ABSTRACT

Compounds having the formula   WHEREIN EACH R is hydrogen, alkyl or hydroxymethyl, at least two R groups being hydroxymethyl, R1 is alkyl, and R2 is hydrogen or alkyl; compositions containing the described compounds and/or Nhydroxymethyl derivatives of other compounds obtained, in addition to the described compounds, by condensing an aliphatic aldehyde with a urea compound; and cellulose-containing textile materials treated with the compounds or compositions. The compounds and compositions impart wrinkle-resistant properties to cellulose-containing cellulose textile materials, such treated materials exhibiting excellent tensile strength and resistance to abrasion.

United States Patent 1 Martin et al.

[ Oct. 21, 1975 Tenn.; Howard M. Lewis, Dallas, Tex.

[73] Assignee: Eastman Kodak Company,

Rochester, NY.

22 Filed: June 25,1973

21 Appl. No.: 373,546

Related U.S. Application Data [62] Division of Ser. No. 102,982, Dec. 30, 1970, Pat. No.

[52] U.S. Cl. 260/256.4 F; 260/256.4 N; 260/256.4 C

[51] Int. Cl. C07D 239/00 [58] Field of Search 260/256.4 F, 256.4 C

[56] References Cited UNITED STATES PATENTS 3,329,519 7/1967 Mills 260/256.4 C 3,630,751 12/1971 Ushioda et al. 260/256.4 C

Primary ExaminerPaul M. Coughlan, Jr. Assistant Examiner-James I-l. Turnipseed Attorney, Agent, or Firm-C. D. Quillen, Jr.; J. Frederick Thomsen [57] ABSTRACT Compounds having the formula wherein each R is hydrogen, alkyl or hydroxymethyl, at least two R groups being hydroxymethyl, R is alkyl, and R is hydrogen or alkyl; compositions containing the described compounds and/or N-hydroxymethyl derivatives of other compounds obtained, in addition to the described compounds, by condensing an aliphatic aldehyde with a urea compound; and cellulosecontaining textile materials treated with the compounds or compositions. The compounds and compositions impart wrinkle-resistant properties to cellulosecontaining cellulose textile materials, such treated materials exhibiting excellent tensile strength and resistance to abrasion.

4 Claims, N0 Drawings NOVEL N-HYDROXYMETHYL COMPOUNDS, COMPOSITIONS CONTAINING SUCH COMPOUNDS AND CELLULOSE-CONTAINING TEXTILE MATERIALS TREATED THEREWITH This is a division of application Ser, No. 102,982 filed Dec. 30, 1970, now U.S. Pat. No. 3,772,292.

This invention concerns certain novel compounds and compositions and certain amino resins derived therefrom which impart wrinkle-resistant properties to cellulosic materials and a method for producing wrinkle-resistant cellulosic materials.

The use of urea-formaldehyde condensates as textile finishes is well known as is the method by which'they are applied to cellulosic textile materials. Several amine-formaldehyde condensates, such as N.N- dimethylolethylene-urea, have been used extensively to render cellulosic textile materials resistant to wrinkling. Such condensates and the methods by which they are applied to cellulose materials are described in U.S. Pat. Nos. 2,777,857; 2,876,062; 2,884,301; 3,041,199; 3,116,967; 3,158,501; 3,216,777; 3,324,062; 3,378,397; and 3,442,905, in Textile Industries, Vol. 123, pages 116 to 127 (October 1959), and in Marsh, Crease Resisting Fabrics, Reinhold Publishing Corporation, New York (1962). Such known condensation compounds, referred to as textile treating resins and as aminoplasts, suffer from a number of disadvantages such as high cost and severely decreasing the tensile strength and abrasion resistance of cellulosic materials treated therewith. It is desirable that textile treating resins impart crease-resistance and dimensional stability to cellulosic materials without adversely affecting the hand or physical properties of the material. It is also important that such textile treating resins can be synthesized from inexpensive materials so that the cost of resin-treated cellulosic materials is not increased substantially. The resins must also be capable of use in standard textile treating machinery and procedures and they must be sufficiently stable so that can be stored and handled over extended periods of time and under various conditions.

We have discovered that the novel compounds and compositions of the invention impart wrinkle-resistant properties to cellulosic material without severely decreasing the tensile strength and abrasion resistance of the material.

Our novel compounds have the general formula and compositions can be used in conjunction with known textile treating resins or the co-products obtained during the preparation of compounds (1) can be separated and employed in admixture with certain known textile treating resins to improve the properties of the latter. The novel compounds and compositions of our invention are prepared according to the equamom:

Step 1: R-CHO RNHCNH Acid, Intermediate Condensate Step 2: Intermediate Condcnsatc- Compound or HCHO Composition wherein R is lower alkyl such as methyl, ethyl, propyl. isobutyl, and butyl and R is hydrogen or lower alkyl. The group represented by R determines the identity of R and R in formula (I). For example, when R is methyl, each R is methyl and R is hydrogen; when R is ethyl, each R' is ethyl and R is methy; and when R is butyl, each R is butyl and R is propyl. When R is hydrogen, the intermediate condensate obtained from Step 1 may contain an unmethylolated dione, i.e. hexahydro-4,5-dialkyl (or 4,4a,5-tria1kyl) pyrimido[4,- 5-d]-pyrimidine-2,7(1H,3H)dione corresponding to formula (1) wherein each R is hydrogen. When R is alkyl, two of the R groups of the unmethylolated dione are alkyl. The position of such alkyl group of formula (I) has not been determined but it is apparent that the positions of N-alkyl substitution may be 1,6; 1,8; 3,6; or 3,8 or a combination of those isomers.

Examples of the aldehydes which can be employed in Step 1 include acetaldehyde, propionaldehyde, butyraldehyde, and valeraldehyde. Urea, methylurea, ethylurea and propylurea and typical urea compounds which can be used in the synthesis of our novel compounds. For ecconomic-reasons, we prefer to use urea in the preparation of our novel compounds and compositions. Acetaldehyde is the preferred aldehyde because of its favorable cost and the excellent properties of the compound and compositions obtained from the acetaldehyde-urea compound condensate. The aldehyde may be added to a solution of urea and catalyst or the aldehyde and a solution of urea may be added to the catalyst. Usually, Step 1 is carried out in the presence of a solvent for the urea compound. Examples of suitable solvents include water, the lower alkanols such as methanol, ethanol, propanol, isopropanol, etc., or mixtures thereof. The weight ratio of reactants to solvent can be varied from 2:1 to 1:10, the amount of solvent not being important. Generally, we prefer to use a minimum amount of solvent which will enable the reaction mixture to be stirred in conventional production equipment and will permit the mixture to be conveniently handled. The acid catalyst employed in Step 1 is not important provided that the acidity of the reaction mixture is maintained at a pH 4 or below, preferably in the range of pH 0.5 to pH 2. Examples of acids which are capable of maintaining the reaction mixture at such a pH are sulfuric, phosphoric, hydrochloric, p-toluenesulfonic, methanesulfonic, and strongly acidic ion-exchange resins such as Dowex 50, a sulfonated polystyrene. Generally, and acid material having an acidity or ionization constant of at least 10 can be employed in the Step 1 reaction. However, the particular acid and the amount thereofwhich can be employed to maintain a pH of 4 or less will be apparent to those skilled in the art. The mole ratio of urea to aldehyde can be varied substantially but preferably is between 1:1 to 1:2, the ratio of about 2:3 being especially preferred. The reaction temperature for Step 1 can be varied between to about 150C. with temperatures in the range of 30 to 80C. being preferred. The reaction time can be varied depending on other reaction conditions such as temperature and acidity. If desired. Step 1 can be carried out at pressures moderately above or below atmospheric pressures although atmospheric pressure gives satisfactory results.

The unmethylolated dione also can be prepared by condensing an aldehyde of the formula R CHO with a pyrimidinylurea compound of the formula wherein R and R are defined above and each R is hydrogen or alkyl at least one of the R groups attached to the pyrimidone ring and one of the R groups of the urea residue being hydrogen. The aldehyde should be added to the pyrimidinylurea compound and acid catalyst using the conditions described above for Step 1. The mole ratio of the pyrimidinyl compound to the aldehyde should be about :1 to about 4:5, the theoretical ratio of about 1:1 being preferred. This technique can be used to prepare unmethylolated dione compounds where the R groups of formula (1) are differ- .ent. The pyrimidinylurea reactant can be substantially pure or it can contain significant amounts of the compounds formed with the pyrimidinyl compound is prepared by condensing a urea compound and an aldehyde similar to the procedure of Step 1.

The components of the intermediate condensate obtained from Step 1 is dependent upon the mole ratio of the urea compound to aldehyde. For example, when equimolar portions of urea or alkylurea and an aldehyde having the formula R"CHO are reacted, the intermediate condensate contains from about 30 to about 40% each of a pyrimidinylurea compound of formula ([1) and unmethylolated dione and about to 40% of unidentifiable compounds. As the ratio of area or alkylurea to aldehyde is decreased from 1:1 to 1:2, the ratio of the pyrimidinylurea compound to the unmethylolated dione is believed also to decrease. For example, when 2 moles of urea are reacted with 3 moles of acetaldehyde, we believe that the resulting condensate contains about 40 to 60% of the unmethylolated dione, about 20 to 30% of the pyrimidinylurea compound and about 20 to 30% of compounds, the structures of which cannot be established. When the intermediate condensate contains significant amounts of dione, the dione can be separated from the intermediate condensate and methylolated according to Step 2 to obtain substantially pure compound of formula (1). The mixture of compounds constituting the intermediate condensate also can be methylolated to obtain a composition having unexpectedly improved properties as a textile treating resin. The co-products formed with the dione in Step 1 can be separated. methylolated and combined with certain known textile treating resins to provide resins exhibiting improved properties.

Step 2 can be carried out in the presence of acid or base. When conducted in a basic medium the pH ofthe reaction mixture should be at least 8 and preferably in the range of9 to 12.5. Examples of catalysts capable of maintaining such a pH include the alkali metal hydroxides, carbonates and bicarbonates such as sodium hydroxide, potassium hydroxide, lithium hydroxide, sodium carbonate. sodium bicarbonate and potassium carbonate. the alkaline earth hydroxides such as bar ium and calcium hydroxide, quaternary ammonium hydroxides such as benzyltrimethylammonium hydroxide and basic ion-exchange resins such as Amberlite 1RA 400 (a strongly basic ammonium hydroxide ionexchange resin). The various basic materials and the amounts thereof which are useful in Step 2 can be determined by those skilled in the art. When using a basic catalyst we have found that the pH of the methylolation reaction mixture decreases significantly as the reaction proceeds to completion. For example, an initial methylolation pH of 12.5 will decrease to 10.3 during Step 2. When Step 2 is conducted under acidic conditions, the pH should be about 0.5 to 5 and preferably about 0.5 to 3. The acids used in step 1 also can be used in Step 2 or more conveniently the pH of the reaction mixture containing the intermediate condensate from Step 1 can be adjusted either with base or acid prior to the addition of the formaldehyde. The amounts of formaldehyde employed in Step 2 can be varied considerably, the optimum amount depending on the ratio of the reactants used in Step 1 and whether'the dione or the crude condensate is being methylolated. When the unpurified intermediate condensate is used, the amount of formaldehyde that is used in Step 2 should be at least 1 mole, preferably about 1.5 moles to about 2.5 moles, per mole of urea used in Step 1. 1f the dione compound obtained from Step 1 is separated from the intermediate condensate mixture, at least 2moles, preferably about 3 moles to about 4.5 moles, of formaldehyde per mole of dione are employed. The compounds of the intermediate condensate, which remain after the removal of the dione, can be methylolated using at least 1, preferably 1.5 to 2.75 mole(s) of formaldehyde per mole of urea used in step 1. The intermediate condensate obtained in Step 1 when the mole ratio of the reactants is 1:1 is methylolated with about 1.5 to about 3 moles of formaldehyde per mole of urea used. The amounts of formaldehyde to be used as described in this paragraph are for unpurified intermediate condensates and dione compounds prepared from urea. The intermediate condensate and dione compounds obtained from alkylurea generally require about 50 to 60% of the abovementioned amounts of formaldehyde. The use of excess formaldehyde in the methylolation of the intermediate condensate, including the dione, pyrimidinylurea and- /or other co-products, generally is not detrimental.

Although the amount of formaldehyde employed determines primarily the number of hydroxymethyl groups present on the dione, the pyrimidinylurea compound and, possibly the other co-products, it is possible that some of the formaldehyde is in equlibrium with the corresponding N-hydroxymethyl derivatives. Thus, a reaction solution prepared using 4.5 moles of formaldehyde per mole of dione derived from urea and an aldehydc is believed to contain a mixture of the di-, triand tetra(hydroxymethyl) compounds. Of the compounds of formula (I), those in which each R group is hydroxymethyl are especially preferred. However, because of the mentioned equilibrium and/or in complete methylolation, the preferred compounds of formula (I) contain as an average, about 3 to about 3.5 hydroxymethyl groups. The formaldehyde employed in Step 2 can be in the form of an aqueous solution or it can be derived from formaldehyde-yielding compounds such as paraformaldehyde. The reaction time for Step 2 will vary from a few minutes to several hours depending upon reaction conditions such as temperature, etc. The solvents which are used in Step 1 can be used in Step 2 in the event that any or all of the compounds constituting the intermediate condensate are isolated. Such a solvent can be supplied from Step 1, if the intermediate condensate compounds are not isolated prior to Step 2, or can be derived from the formaldehyde solution used. The reaction can be performed at about to about l0OC., preferably between and 75C.

Our novel compositions obtained by the methylolation of an intermediate condensate prepared from a urea compound and an aldehyde reacted in a mole of urea compound to aldehyde of 2 to 3 or more contain about 40 to 60% of a compound of formula (I) and about 40 to 60% of methylolated compounds which have not been conclusively identified. However, we believe that about 20 to of such a composition is a N-polymethylol pyrimidinylurea compound of the formula N o Os l is. (in) \R wherein R, R and R are defined hereinabove. The remaining 20 to 30% of the composition consists of one or more other methylol derivations of the unidentified compounds formed during Step 1. The novel compositions obtained by methylolating an intermediate condensate, prepared from a urea compound and an aldehyde reacted according to Step 1 in a urea compound: aldehyde ratio of about 1:1, contain (1), (II) and co products. Although the number and positions of the methylol groups of the compound of formula (III) has not been established, we believe that the N- polymethylolpyrimidinylurea component of our novel compositions is a mixture of compounds which contains two, three or aossibly, more methylol groups.

The novel compounds and compositions described hereinabove exhibit excellent properties when applied to cellulose materials. including regenerated cellulose (rayon) according to known procedures. These desirable properties include high wrinkle-resistance, good color (whiteness), resistance to acid and basic hydrolysis, good washed appearance, no significant effect on dye shade when used on colored cellulose materials, and rapid cure. The relatively low cost of the novel compounds and compositions is an especially advantageous feature. The novel compositions do not decrease the tensile strength and abrasion resistance of cellulosic materials to the extent which known durable press compounds do. The novel compositions, which consist essentially of 1) one or more compounds of formula (I) and (2) the methylolated co-products formed during the aldehyde-urea condensation described above, are particularly advantageous. The compositions are economical since expensive isolation and purification procedures are not required during their synthesis. The brasion resistance of cellulose materials treated with the novel compositions not only is superior to that of cellulose materials treated with known durable press resins, but, surprisingly, is superior to that of cellulose materials treated with a substantially pure compound of formula (I).

Cellulose-containing textile materials rendered resistance to wrinkling by treatment thereof with at least one of our novel compounds or compositions constitutes another aspect of our invention. The novel durable press compounds and compositions are applied to cellulose-containing textile materials according to con ventional procedures in order to produce a high degree of wrinkle resistance thereto. The cellulose materials which can be rendered wrinkle resistant by our novel compounds and compositions include fibers, yarns, filaments, formed fabric, whether woven or non-woven, felted or otherwise formed, containing cellulose fiber prepared from cotton, rayon, linen, flax and other cellulose materials. The cellulose textile materials can be employed in combination with other non-cellulose materials such as, for example, blends of cellulose textile materials with other natural or synthetic fibers such as wool, nylon, acrylic, modacrylic and polyester fibers. The novel compounds and compositions also can be used on any fiber, fabric or other material which contain hydroxyl groups, possibly built in, which are capable of undergoing reaction with the methylol groups of our compounds and compositions.

The compounds and compositions of our invention are applied to cellulose materials, preferably a formed, cellulose textile material, with a suitable curing catalyst from an aqueous solution. The solution of our compounds and compositions and curing catalyst can be applied to cellulose materials by immersion, padding, spraying and the like, followed when necessary, by squeezing, hydroextraction or similar processes in order to deposit the desired amount of resin solids onto the fabric. Any application technique can be employed so long as it deposits our novel compounds and compositions uniformly on the textile material.

The concentration of the novel compounds or compositions in the treating solution can be varied so that about 1 to about 20% of the particular durable press compound or composition, based on the weight of the textile material, is deposited thereon. The amount of the compound or composition deposited o'n the textile material will depend on the type of fabric being treated. For example, in treating fibrous cellulose textile materials, concentrations of about 1 to about 15%, based on the weight of the textile material of the compound or composition, have been found to give good durable press characteristics. l

The compounds which can be employed as catalysts in the curing of our novel compounds and compositions to form the amino resins, described in detail hereinbelow, are well known to those skilled in the art concerning durable press compounds and the amino resins. Such amino resin-forming compounds are acids of acid-yielding materials including inorganic acids such as hydrochloric. nitric, phosphoric and sulfuric acid; organic acids such as formic acid, oxalic acid, tartaric acid and trichloroacetic acid; amine hydrochlorides such as 2-methyl-2-aminopropanol hydrochloride and monoethanolamine hydrochloride, ammonium chloride; and acid-forming metallic salts such as magnesium chloride, zinc chloride, zinc nitrate, zinc acetate, zinc fluoroborate, aluminum nitrate. The concentration of catalyst employed may range from about 0.01 to about 25% or higher based, on the-weight of the resin-forming compound or composition employed, depending upon the particular catalyst and curing condition employed. For example, 0.1 to 10% of a free acid, 0.5 to b 20% of ammonium chloride, 1.0 to 10% of an amine hydrochloride and about 0.01 to about 10% ofa metallic salt may be used.

Following the application of the compound or composition and curing catalyst to the textile material, the material is exposed to drying and curing conditions to impart to the material durable press properties. The drying and curing operation may be carried out in one or two steps. Dryin can be performed at ambient or elevated temperatures. Curing is accomplished by heating the treated cellulose material to heat of about 250 to about 500F. for 2 seconds to about 4 minutes. The time and temperature necessary for curing are dependent on one another, the amino resin-forming catalyst employed, and on whether the drying and curing is carried out in one or two steps. Thus, an infinite combination of catalyst levels, curing temperatures, exposure times and catalysts may be employed. For example, when drying and curing is carried out in a combined operation, a time of from 1 minute to about 5 minutes and a temperature of about 300 to 400F. can be employed. When the cellulose material has been dried prior to curing, time of about 1 to 3 minutes at a temperature of about 300 to about 400F. gives good results.

The curing properties possessed by our novel compounds and compositions render then suitable for use in the flash curing technique of curing treated cellulose material in which very high temperatures such as about 400 to about 1200F. and high production speed, i.e. short curing times such as 6 seconds, are employed. Drying and/or curing may be performed in a forced air oven or, when very high curing temperatures are desired, in an infra-red curing oven. Our novel compounds and compositions can also be used in the known post-cure procedure in which a cellulosecontaining textile material is treated with one of our novel compounds or compositions and a curing catalyst and then dried, preferably at a temperature not above 250F. Textile garments can be manufactured from the sensitized cellulose textile materials and then the compound or composition can be cured as described above to impart wrinkle-resistant properties to the garment.

The treating solution, i.e. the solution containing the curing catalyst and at least one of our novel compounds or compositions, may contain other auxiliary agents commonly employed in durable press finishing of textile materials. Softeners, wetting agents, handbuilders, scrooping agents, anti-soiling agents, optical brighteners, water repellants and flame retardants are examples of other chemicals which can be present in the treating solution. Typical of the softeners which can be used are silicone dispersions. polyethylene emulsions, fatty estcrsof glycerin, polyethylene glycol, sull'onated oils such as sulfonated olive oil, a formic acid emulsion of trialkanolaminomonostearate, and stearic acidethylene oxide condensates. Prior to the addition of the curing catalyst to the solution of our novel compound or composition, the pH of the solution should be adjusted to 7 or less, preferably about 5.5 to about 7.0.

Another aspect of our invention is the novel amino resins derived from our novel compounds and compositions. During the curing of the compound or composition on a cellulose-containing textile material, the watcr-soluble compound or composition is chemically affixed to the cellulose molecules due to the reaction of two or more hydroxymethyl groups ofthe compound or composition with two or more hydroxy groups of one or more cellulose chains. The desirable durable press properties which our novel compounds and compositions impart to cellulose-containing textile materials results from the cross-linking of the cellulose molecules by the residues of our novel compounds and the components of our novel compositions. The novel amino resins, consisting essentially of the residue of the compounds and compositions, may be monomeric, oligomeric or polymeric. The oligomeric amino resins result from the condensation of one of the compounds of formula (I) with itself of the condensation of the components of our novel compositions with one another according to conventional polyglycol formation during the curing of the compounds on the cellulosic material. Since the novel compounds and at least some of the components of the novel compositions are di-, tri-, and tetra-functional, our novel oligomeric resins may be both linear and branch-chain. Although neither the occurrence nor the extent of oligomerization can be determined analytically, it is believed that the resins derived from the novel compositions are in part oligomeric while those derived from the novel compounds essentially are monomeric. The degree of polymerization of both the novel compounds and the components of the novel compositions can be increased significantly if a polymer-forming catalyst, such as zinc acetate or zirconium acetate, is applied with one of our novel compounds or compositions to a cellulose mate rial followed by curing at a low temperature. A conventional amino resinforming catalyst, such as that described previously, then can be applied to the polymercontaining cellulose material to effect cross-linking of the cellulose molecules.

Cellulose-containing textile materials and especially cotton and cotton-polester textile materials exhibit good resistance to wrinkling and excellent tensile strength and abrasion resistance are obtained by the following procedure:

a. about 6 to about 12%, based on the weight of the cellulosic material, of the composition obtained by:

l. contacting acetaldehyde with urea in a ureazacetaldehyde mole ratio of about 2:3 at a temperature of about 30 to about C. at a pH of about 0.5 to about 2 in the presence of water to form an intermediate condensate, and

2. contacting the aqueous suspension of the intermediate condensate with about 1.75 to about 2.25 moles of formaldehyde per mole of urea used in Step (1) at a temperature of about 25 to about 55C. and a pH of about 10 to about 12.5,

and about 1 to about 1071 based on the weight of the composition, of zinc nitrate, magnesium chloride or zinc chloride. is applied to the cellulosic material; b. the cellulosic material is dried; and

sodium carbonate, and 135 ml. of water gives a solution containing about 45% of N,N'-dimethyl0lhexahydro 4,5-dimethylpyrimido[4,5-d]pyrimidine-2,7-

(1H,3H )dione.

c. the cellulosic material then is heated to a temperature of about 280 to about 425F. for about 6 to EXAMPLE 3 about 120 seconds.

The i required for Curing p ((5) is inversely To a stirred solution of 960 g. (16 moles) of urea and Proportional to the temperature used For ample, a 320 ml. of concentrated hydrochloric acid in 1440 ml. normal rate of curing requires the treated material to of water, at an initial temperature of 13C, is added be heated to "lbmn 3000 m about f t about 8 1060 g. (24 moles) of acetaldehyde during 45 minutes. about 90 Seconds h rapld Curmg rates m The reaction is exothermic and cooling is used to mainwhich the treated material is heated for about 5 to win a temperature of 500 to This temperature is about sfconds f temperatures of about 3750 to maintained for an additional 30 minues and then lowdbout 425 hlgher' ered to C. during 1.5 hours. The resulting suspenpreplamnon our "9 P P compos" sion is neutralized to pH 7 with 608 g. of 25% aqueous t1ons, 3.1111110 resins, wrinkle-resistant cellulose- Sodium hydroxide made basic (PH 105) with 135 g. containing textile materials and textile finishing cmpoof Sodium bicarbonate and 170 of Sodium carbom sitions 1S further illustrated by the following examples. 20 ate, and treatead with 3000 g (36 moles) of 36% aque All percentages are by we1ght unless stated otherwlse. ous formaldehyde. The temperature is raised to 500C EXAMPLE 1 during minutes and maintained at 50 to 55C. for 2 hours. The resulting clear solution contains about P 1782 of hexahydro 25 2540 g. of solids of which approximately 5071 is poly-ndlmethylpynmldmidlpyllmldme'zfl' methylol hexahydro-4,5-dimethypyrimido[4,5- (lHg3Hldl9nei 3430 (41-7 moles) a d]pyrimidine-2.7-(11-1,3H)dione, 25% of which is bemalm solution, 574 g. of water, 15.2 g. of sodrum bicarlieved to be pO1y N methy]O| hexahydro 4 methyl 6 bonate and 109.2 g. sodium carbonate 1s stirred and ureidoapyrimidonev and 25% of which is methyl0l heataed to 55 C. for 1 hour and held at 55 to 57 C. for ated unknowns The assumption that the product 2 additional hours. The resulting solution is cooled to 30 tamed contains approximately of the dione give a solution containing 49% solids, mostly poly-N- pound i b d upon h mount of hexahydro-4,5- yl y f i py 1 5- dimethylpyrimido[4, d]pyrimidine-2,7-(1H,3H)-dione 1Py when 435 of thls which is isolated from the products obtained by the Solution is allowed to Stand at for Several days, condensation of urea and acetaldehyde as described 37.0 g. of a N,N,N"-trimethylolhexahydro-4,5- 35 bove hy py l 1-pyr i in -2.7- Each of the examples in Table l is a repetition of the (lH. H)di n ep r e n i recovered y fil r n general procedure employed in Example 3 with various and dried under vacuum. This compound melts and pechanges in the process variables. Each of the composilymerizes at about 205C, depending on the rate of tions obtained from Examples 4 through 16 impart duheating. 4O rable press properties to cellulosic textile materials.

TABLE I Ex. Moles Moles Amt. Acid Time, Max. Amt. HCHO, Temp., Time. No. CHzCHO Urea H2O, ml. Amt.. ml. Hr. Temp., "C. pH Moles C. Hr. 4 24 16 1440 HCI, 320 2 10.5 36 55 2 5 24 16 1440 HCl, 320 2 55 10.5 i 20 5s 2 6 24 16 1440 not, 64 2 55 10.5 36 55 2 7 32 16 1440 HC1,320 2 55 10.5 36 5s 2 8 24 16 700 HCl, 320 2 55 10.5 36 55 2 9 24 16 1440 H,s0,, 30 2 55 10.5 36 55 2 10 24 16 1440 HCl, 320 1 120 10.5 36 55 2 11 24 16 1440 HCl, 320 4 10 10.5 36 55 2 12 24 16 1440 H 1 0 100 2 55 10.5 36 5s 2 13 24 16 1440 HCl. 320 2 55 12.0 36 25 3 14 24 16 1440 HCl. 320 2 55 9.5 36 100 0.5 15 24 16 1000 H280 10 5 100 10.5 36 55 2 16 20 16 1440 HCI, 320 2 55 10.5 36 55 2 Anal. Calcd. for C H N O C, 45.8; H, 7.0; N. EXAMPLE 17 19.4; combined CH O, 31.3. Found: C, 46.2; H, 7.1; N, 19.5; combined CH O, 31.4.

EXAMPLE 2 Following the general directions of Example 1; 158 g. (0.8 mole) of hexahydro-4,5-dimthylpyrimido[4,5- d]-pyrimidine-2,7-(1H,3H)dione, 164 g. (2.0 moles) of 36.5% formalin, 1.35 g. sodium bicarbonate, 1.71 g. of

To a 22 liter, 3-neck flask fitted with stirrer, thermometer, dropping funnel, and dry ice-isopropanol condensor is added 3432 g. water,l338 g. of 32% hydrochloric acid, and 2880 g. (48.0 mole) urea. 3180 g. (72 Mole) acetaldehyde is added over a -minute period. The exothermic reaction is kept at 48 to 52C. with an ice-water bath. The temperature is maintained at about 50C. for an additional 30 minutes, then lowered to 30 to 35C. over a two-hour period and finally lowered to 25C. The resulting suspension is neutralized to pH 7.0 by the addition of 964.8 g. of 50% sodium hydroxide solution. The reaction mixture is cooled to ambient temperatures, the pH is adjusted to about 12.5 by the addition of 90.3 g. of 50% sodium hydroxide solution, and then 2880 g. (96.0 moles) of flake paraformaldehyde is added. The reaction mixture is heated at 30 to 35C. for 50 minutes and then heated at about 50C. for 2 hours 15 minutes. The mixture is then cooled to below 30C.'and neutralized to a pH of about 7.0 with 83.9 g. of 32% hyrochloric acid. Employing 90 g. of a filtering aid, the reaction mixture is filtered under vacuum to obtain 14.3 kg. ofa clear solution calculated to contain approximately 51.3% solids consisting essentially of poly-N-methylol hexahydro- 4,5-dimethylpyrimido[4,5-d]pyrirnidine-2,7- (1H,3H)dione and poly-N-methylol coproducts.

EXAMPLE 18 According to the procedure described in Example 17, 480 g. (8.0 moles) urea and 530 g. 12.0 moles) acetaldehyde are condensed in the presence of 540 g. water and 223 g. of 32%- hydrochloric acid. The reaction mixture is cooled and 185.7 g. of 50% sodium hydroxide solution is added to give a pH of 11.7. Then 420 g. (about 14.0 moles) of flake paraformaldehyde is added followed by 30.5 g. of 50%- sodium hydroxide solution. The mixture is brought to 80C. over a 45- minute period and held at that temperature for two hours. To the cooled reaction mixture, having a pH of about 8.8, is added 3.2 g. of a plant hydrochloric acid to give a pH of 7.1. The mixture is then filtered under vacuum to obtain 2359 g. of clear solution containing approximately 50.3% of the solids described in Example 17.

EXAMPLE 19 The synthesis described in Example 18 is repeated except that the reaction mixture is heated at about 50C. for ten hours after the addition of the peraformaldehyde. The clear solution obtained by filtering the reaction mixture contains 49.8 solids consisting essentially of the poly-N-methylol compounds described in Example 17.

EXAMPLE 20 To a stirred solution of 148 g. (2 moles) of methylurea and 40 ml. of 37% hydrochloric acid in 180 ml. of water, at an initial temperature of 20C., 180 ml. (3.2 moles) of acetaldehyde is added during minutes. The reaction is exothermic and cooling is used to maintain a temperature of 55C. A solid forms near the end of the addition. The temperature is maintained at 55C. for an additional 1 hour and then lowered slowly to 25C. to give 80 g. of hexahydro-4,5- dimethyl-N,N-dimethylpyrimido[4,5-d]pyrimidine- 2,7-(1H3H)dione, m.p. 3093l 1C. Recrystallization from 700 ml. of boiling water gives 53 g. (23%) of crystals m.p. 311319C. (decomp.). Anal. Calcd. for C H N O C, 53.1; H, 8.0; N, 24.8. Found: C, 53.2; [-1, 8.0; N, 24.8. An additional quantity of product precipitates from the filtrate when it is treated with Nal-lCO solution. Treatment of the dione obtained with 2 moles of formaldehyde yields the compound hexahydro-4,5-dimethyl-N,N-dimethyl-N,N- dihydroxymethylpyrimidol4,5-d]pyrirnidine-2,7-( 1, H,H)dione.

EXAMPLE 21 To a stirred solution of 480 g. (8 moles) of urea and ml. of concentrated hydrochloric acid in 720 ml. of water, at an initial temperature of 15C., is added 528 g. (12.0 moles) of acetaldehyde during 45 minutes. The exothermic reaction is held at 50C. by a cooling bath. A temperature of 40 to 50C. is maintained for 2 hours. The resulting suspension is cooled to 0C. and neutralized to pH 7 with 25% aqueous sodium hydroxide. The resulting suspension is filtered to remove 439 g. of hexahydro-4,5-dimethylpyrimidod[4,5- d]pyrimidine-2,7-(1H.3H)dione dihydrate. To the filtrate is added 3.38 g. of sodium bicarbonate. 4.26 g. of sodium carbonate and 722 g. (9.0 moles) of 37% aqueous formaldehyde. The solution, which has a pH of about 10, is heated at 50C. for 2 hours. The resulting solution is clear, light colored and contains a mixture of about 12% of poly-N-methylol hexahydro-4,5- dimethylpyrimido[4,5-d]pyrimidine-2,7-( lH,3H)dione and 40 to 50% each of poly-N-methylol(hexahydro-6- methyl-2-oxo-4-pyrimidinyl)urea and methylolated unknowns.

EXAMPLE 22 To a stirred solution of g. (3.0 moles) of urea and 60 ml. of concentrated hydrochloric acid in 270 ml. of water is added 261 g. (4.5 moles) of propionaldehyde during 45 minutes. The exothermic reaction is controlled at 45 to 50C. by a cooling bath during the addition. After 1 hour a solid precipitates. The reaction mixture is kept at 50C. for 1 hour, then cooled to 30C. during 2.5 hours. After this time, it is neutralized to pH 7 using 25% aqueous sodium hydroxide, then made basic by the addition of 2.54 g. of sodium bicarbonate and 3.2 g. of sodium carbonate, and treated with 540 g. (6.75 moles) of 37% aqueous formaldehyde. This mixture is held at 50C. for 2.5 hours. The resulting solution is a clear light straw yellow solution.

EXAMPLE 23' To a stirred solution of 180 g. (3.0 moles) of urea and 60 ml. of concentrated hydrochloric acid in 135 ml. of water and 135 g. of methanol is added 324 g. (4.5 moles) of distilled n-butyraldehyde over a period of 40 minutes. The solution is stirred for 1.5 hours at 40 to 50C., neutralized to pH 7 with sodium hydroxide and then 2.54 g. of sodium bicarbonate and 3.20 g. of sodium carbonate are added. Finally 540 g. (6.75 moles) of 37% aqueous formaldehyde is added and the solution stirred at 50 to 54C. for 2.5 hours. The resulting solution is almost colorless.

EXAMPLE 24 1 To a stirred solution of 960 g. 16 moles) of urea and 320 ml. of concentrated hydrochloric acid in 1440 ml. of water, at an initial temperature of 13C. is added 704 g. (16 moles) of acetaldehyde during 30 minutes. The reaction is exothermic and cooling is used to maintain a temperature of 50 to 55C. The resulting suspension is neutralized to pH 12.5 with aqueous sodium hydroxide. and then 1200 g. (40 moles) of paraformaldehyde is added. The reaction mixture is heated at 30 to 35C. for 50 minutes and then heated at about 50C. for 6 hours. The mixtue is then cooled to 30C. and neutralized to pH of about 7.0 using hydrochloric acid. The

' resulting material is an aqueous solution of solids consisting of about 30-40% poly-N-methylol(hexahydro-6- methyl-2-oxo-4-pyrimidinyl)urea, 30-40% of the poly- N-methylol dione, and 40% of poly-N-methylol coproducts.

EXAMPLE To a stired mixture of 172 g. (1.0 mole) of hexahydro-6-methyl2-oxo-4-pyrimidinylurea, 75 ml. of concentrated hydrochloric acid and 150 ml. of water is added 44 g. (1.0 mole) of acetaldehyde over a period of minutes. The reaction temperature is controlled at 50C. during the addition and for 2 hours in addition. The reaction is cooled to ambient temperatures and the pH adjusted to 12.5 by the addition of 50% sodium hydroxide solution and then 120 g. (4 moles) of paraformaldehyde is added. The mixture is heated at 30 to C. for 1 hour and at 50C. for 2 hours. The mixture is then cooled to 25C. and the pH adjusted to 7.0 with hydrochloric acid. The resulting clear solution contains poly-N-methylol hexahydro-4,5-dimethylpyrimido[4,5- d]pyrimidine-2,7-(1H,3H)dione and poly-N-methylol coproducts.

EXAMPLE 26 To a stirred mixture of 172 g. (1.0 mole) of'hexahydro-6-methyl2-oxo-4-pyrimidinylurea, 75 ml. of concentrated hydrochloric acid and 150 ml. of water is added 58 g. (1.0 mole) of propionaldehyde over a period of 45 minutes. The reaction temperature is controlled at 55C. during the addition and for 3 hours in addition. The reaction mixture is cooled to ambient temperatures and the pH adjusted to 12.5 by the addition of 50% sodium hydroxide solution, and then 120 g. (4 moles) of paraformaldehyde is added. The mixture is heated at 30 to 35C. for 1 hour and at 50C. for 2 hours. The mixture is then cooled to 25C. and the pH adjusted to 7.0 with hydrochloric acid. The clear solution consists essentially of poly-N-methylol hexahydro-4-ethyl-5-methylpyrimido[4,5-d]pyrimidine-2,7- (1H,3H)dione and poly-N-methylol co-products.

EXAMPLE 27 To a mixture of 180 g. urea, 270 ml. water and 71.4 g. hydrochloric acid is added 198 g. acetaldehyde over a 30-minute period at 50 to 55C. Heating at 50C. is continued for an additional 30 minutes and the temperature of the reaction mixture is allowed to decrease to 25C. over a 3-hour period. The pH of the mixture is adjusted to about 2.8 with 110 g. of 25% sodium hydroxide solution. 542 g. of 37.4% formalin solution is added and the mixtue is heated at 54C. for 4 hours. The resulting amber solution is believed to contain about 30 to of a N-methylol compounds, of which 3040% is poly'N-methylol hexahydro-4,5- dimethylpyrimido[4,5-d]pyrimidine-2,7- (1H,3H)dione. 3040% is the poly-N-methylol dione, and 20-40% is poly-N-methylol co-products.

EXAMPLE 28 123 g. ()fa 50% solution of poly-N-methylol hexahydro-4,5-dimethylpyrimido[4,5-d]pyrimidine-2,7- (1H,3H )dione, prepared according to Example 1, is diluted with an equal volume of water and adjusted to pH of 5.5 with acetic acid. A pad bath is prepared consisting of the above solution, 24.6 g. of a 30% aqueous zinc nitrate solution, 1.0 g. of a nonionic wetting agent and enough water to give a total solution weight of 492 g. A sample of 100% cotton print cloth (80 X 80 inches) is padded through the resin bath at 120F. to obtain a wet pick-up of approximately 60% (about 7.5% of resin add-on). The treated fabric is then dried at 220F. and cured at 340Fv for seconds. Wrinkle recovery, as determined by the standard wrinkle recovery test (AATCC-66-l968), shows a value of 300 (W and F) as opposed to 190 (W and F) for an unfinished cotton controlv The resulting cloth has a good white color, good hand, good resistance to laundering and does not yellow upon ironing after exposure to household bleaching solutions.

EXAMPLE 29 A cotton fabric sample is padded in a bath containing 96 g. ofa 45% solution of N,N-dimethylol hexahydro-4,S-dimethylprimidol4,5-d]pyrimidine-2.7- (1H,3H)dione prepared as described as Example 2, 19.0 g. of a 25% zinc nitrate solution and 0.8 g. of a non-ionic wetting agent in 269 g. water. The treated fabric is dried, cured and evaluated as described in Ex ample 28. The finished fabric has a wrinkle recovery value of 269 (W and F) versus 190 (W and F) for the unfinished cotton control.

EXAMPLE 30 A poly-N-methylol hexahydro-4,5- dimethylpyrimido[4,5-d]pyrimidine-2,7-(1H,3H)dione is prepared by reacting formaldehyde with the corresponding unmethylolated dione in a molar ratio 5:1 according to the procedure employed in Example 1. A solution consisting of 25% of the polymethylol dione, 5% of a 25% zinc nitrate solution and 0.2% non-ionic wetting agent, adjusted to a pH of 5.5 with acetic acid, is applied to a cotton fabric as described in Example 28. The padded fabric is dried at 220F., and cured at 340F. for 90 seconds. The finished fabric has a wrinkle recovery value of 283 (W and F) while the unfinished cotton control has a value of 192 (W and F).

EXAMPLE 31 EXAMPLE 32 A pad bath containing 25% (125 g.) of 50% solution of the compound prepared as described in Example 1, 5% (25 g. of 25% solution')zinc nitrate, 0.5% (2.5 g.) of a nonionic wetting agent, and 69.5% water is prepared and applied, at F. (60% wet pick-up), to a 100% cotton fabric. The fabric is dried at 220F. and then 21 samples of the fabric are cured for the periods and at the temperatures set forth below. The wrinkle recovery values of the finished samples are determined as described herinabove.

Temperature Time Wrinkle Recovery (W and F) 320F. 90 sec. 270 320F. 2 min. 279 320F. 3 min. 284 340F. 30 sec. 277 340F. 60 sec. 279

-Continued Temperature Time Wrinkle Recovery (W and F) Sample Exposure Wrinkle Recovery 340F. 90 Time. Minutes (W and F) 340F. 2 min. 288 340F. 3 min. 293 5 246 340F. 4 min. 303 350F. 30 sec. 290 350F. 60 sec. 291 350F. 90 sec. 290 350F. 2 min. 294 10 350F. 3 min. 290 350F. 4 min. 304 252 380F. 30 sec. 293 5 254 380F. 60 sec. 291 380F. 90 sec. 294 380F. 2 min. 294 380F. 3 min, 292 15 380F. 4 min. 293

The above data show that our novel compounds tend to cure rapidly. For example, the wrinkle recovery results obtained by curing at 350F. for 30 seconds are comparable to those obtained at 340F. for seconds or at 380F. for 30 seconds. This rapid cure property is advantageous in flash curing systems commonly used by textile finishing plants to increase production.

EXAMPLE 33 A pad bath containing: (a) 25% (5,000 g.) of a 45% solutioon of the polymethylol dione resin prepared as described in Example 1 (pH adjusted to 5.5 with acetic acid), (b) 5% (1,000 g. of a 25% solution) zinc nitrate, (c) 0.2% (40 g.) of a non-ionic wetting agent, and (d) 13,960 g. water is prepared. A blanket consisting of a cotton fabric portion, a 100% rayon fabric portion and a 50/50 poly(ethylene terephthalate)-cotton blend fabric portion is padded in the bath at F. The blanket is dried at 220F. on a tenter frame and then cured at 350F. for 90 seconds. The wrinkle recovery values of the three different fabric portions are described below.

Wrinkle Recovery Finished Fabric Total Degrees (W and F) 100% cotton 270 1007: rayon 320 50/50 cotton-polyester blend 282 Unfinished Fabric 100% cotton 175 100% rayon 266 50/50 cotton-polyester blend 226 The fabric of 50/50 polyester-cotton blend has washed appearance ratings (AATCC 88A-l964T) of 3.3, 3.5 and 3.5 after undergoing 2, 3 and 5 laundry cycles F. respectively.

EXAMPLE 34 Eleven samples of a cotton fabric finished as described in Example 28 are placed in 0.02 N- hydrochloric acid. Every 5 minutes one of the samples is removed, rinsed, neutralized and dried. The wrinkle recovery value for each sample is then determined. The results, summarized below, establish that poly-N- methylol hexahydro-4,5-dimethylpyrimido[4,5- d]pyrimidine-2,7-(1H,3H)dione exhibits excellent re sistance to acid hdyrolysis.

The wrinkle recovery value for an enexposed, unfinished cotton control fabric is (W and F).

EXAMPLE 35 A cotton fabric is padded with a poly-N-methylol dione resin and portions of the treated fabric are dried and cured as described in Example 28 except that varying amounts of zine nitrate catalyst are used. The wrinkle recovery values of the fabric samples containing or padded with different amounts of catalyst are:

Wrinkle Catalyst Concentration Recovery (W and F) 5% (25% zinc nitrate solution) 278 6% (25% zinc nitrate solution) 277 7% (25% zinc nitrate solution) 284 8% (25% zinc nitrate solution) 286 10% (25% zinc nitrate solution) 287 12% (25% zinc nitrate solution) 290 Unfinished cotton control 186 The above values show that no significant improvements result from the use of catalyst concentrations higher than those used in the preceding examples.

EXAMPLE 36 X7: Resin Wrinkle Recovery (W and F) 10 267 15 282 20 297 25 294 Unfinished Cotton Control 203 The wrinkle recovery values show that the novel dione compounds are effective durable press resins when present on cotton fabrics in widely varying amounts.

EXAMPLE 37 Samples of cotton fabric treated, dried and cured as described in Example 28 are immersed in 0.03 N sodium hydroxide at 140F. for 1 houraThe dried sample has a wrinkle recovery value of 255 (W and F), as compared to a value of 277 for an identical resinfinished fabric which is not exposed to sodium hydroxide, which demonstrates that the novel N-methylol dione compounds are resistant to alkaline hydrolysis.

EXAMPLE 38 Samples of cottom fabric which are resin finished as described in Example 28 are tested for chlorine retention according to i AATCC Standard Test method 92-1967. The samples exposed to hypochlorite bleach are scorched and'tested for strength loss as described in the test. The fabrics retain their whiteness in the scorched areas and lose only about 5% tensile strength which is comparable to the tensile strength loss of an unfinished cotton sample tested in the same manner. The chlorine retention properties of the novel dione resins can be improved by the addition of chemicals commonly used in conjunction with known testile resins for that purpose.

EXAMPLE 39 To determine the usefulness of the novel dione compounds for post-cure applications, cotton fabric samples are treated with a dione resin as described in Example 28. The treated samples are dried at 220F. but are not cured. These sensitized samples are stored for 4 months (65% relative humidity and 70F.) and then cured at 330F. for minutes. The samples have a wrinkle recovery value (W and F) of 277, as compared to a value of 242 W and F) for a treated but uncured sample which had also been stored for four months. These results show that the novel resinsare stable to storage.

EXAMPLE 40 The novel dione compounds do not affect detrimentally the light-fastness of dyes which are applied to the finished cotton fabrics. Using the dyes listed below, cotton fabric samples are dyed with the dyes listed below and then a portion of each of the dyed fabrics is finished as described in Example 28. The dyed, resinfinished samples and the dyed, untreated control fabrics are exposed to a Fade-Ometer according to the standard light-fastness test. The following results are obtained:

Similar results occur if the dyeis applied to a resinfinished cotton fabric. 7

EXAMPLE 41 V A pad bath containing 444 g. ofa 34% solids solution from Example 3, g. of a 25% zinc nitrate solution, 2 g. of a non-ionic wetting agent and 456 ml. water is prepared. The pH of the diluted resin solution is lowered to 5.5 with acetic acid before addition of the catalyst. The catalyst is also diluted with water before addition to the resin bath. A sample of 100% cotton print cloth is padded through the resin bath (120F.) to obtain a wet pick-up of approximately 60% (about 7% resin solids add-on). The treated fabric is then dried at 220F. and cured at 330F. for seconds. The resinfinished fabric has a wrinkle recovery value of 296 (W and F) whereas an unfinished cotton control has a value of 213.

EXAMPLE 42 A pad bath containing 133 g. ofa 34% solids solution of the resin from Example 3, 24 g. of a 10% zinc nitrate solution, 0.6 g. of a non-ionic wetting agent and 143 g. of water is prepared. The pH of the diluted product is lowered to 5.5 with dilute (25%) hydrochloric acid before addition of the catalyst. A sample of cotton print cloth is padded through the resin bath F.) to obtain a wet-pick-up of approximately 60% (about 9% solids on the weight of the fabric). The treated fabric is dried at 220F. and cured at 330F. for 90 seconds. The resin-finished cotton fabric has a wrinkle recovery value of 294 while an unfinished cotton control fabric has a wrinkle recovery value of 192.

EXAMPLE 43 The padded fabrics are dried at 240F. in a horizontal position and cured for 90 seconds at 340F. The fabrics are then after-washed in a solution containing 1 g./1.

tetrasodium pyrophosphate and 0.5 g./1. Igepon T-51 at Hours Light-fastness Resin Finished Zinc Magnesium Nitrate Chloride Catalyst 1 Catalyst Superlitefast Gray LVL Superlitefast Gray LVL Vat Blue 6 I Vat Blue 6 Direct Blue 191 Direct Blue 191,

Sol-Aqua-Fast Red RL Sol-Squa-Fast Red RL Vat Brown 3 Vat Brown 3 Vat Orange 4 Unfinished Control 120F. for 1 minute. The test data set forth below show that 100% cotton and polyester/cotton materials treated with one of our compositions exhibit good resistance to wrinkling and excellent tensile strength and Cotton and cotton-polyester fabrics are treated and cured as described in Example 43 except that 22.6% of 40 EXAMPLE 45 Samples of 100% cotton fabric are padded in a bath containing varying concentrations of resin and catalyst.

abrasion resistance. v Eight baths contalnmg X g. of a 34% sol1ds s0lut1on of the resin prepared as described in Example 3 (the pH of which was adjusted to 5.5 with dilute HCl), Y 100% Polyester/ Comm Comm g. of zmc nrtrate solut1on), 0.6 g. of a non-1on1c Wrinkle Recovery (Degrees) Fabric Fabric 10 wetting agent, and Z g. water. A cotton fabric is pad- W3 129 138 ded in one of the baths, dried and cured as described m s 128 135 in the preceding'example and then wrinkle recovery F T s h 257 273 values of the resin-finished fabrics and an unfinished gfi l'i f-fi'g gi'fgz cotton control fabric are determined. The composition w 56] 1201 l 5 of each of the eight baths, the wrinkle recovery value Filling 25.1 56.8 of a resinfinished fabric padded in the particular bath, i q-m g gfg and the wrinkle recovery value of the unfinished cotton warp 1300 3200 control are set forth in Table [1. These values indicate Fil1ing 900 1500 that the optimum resin solids level on the fabrics is apagf gg% y sa g g 5 2O proximately 7.5% to 9% based on the weight of the fabric.

TABLE I1 Resin Solids X Y Z Solids on Wrinkle Recovery Bath in Bath (Resin, g.) (Catalyst. g.) (Water, g.) Fabric Value (W and F) 1 2.5% 22 4 274 1.5% 226 2 5.0% 44 8 248 3.0% 244 3 7.5% 66 12 222 4.5% 254 4 10.0% 88 16 196 6.0% 277 5 12.5% 110 170 7.5% 302 6 15.0% v 133 24 143 9.0% 311 7 17.5% 155 28 117 10.5% 309 8 20.0% 177 32 91 12.0% 300 Unfinished Cotton Control Fabric 210 EXAMPLE 44 EXAMPLE 46 The procedure described in Example is repeated except that 133 g. of a 34% solids solution of the resin is used in each of the eight baths and the concentration of catalyst and the amount of water are varied. The wrinkle recovery data set forth below for the resinfinished samples indicate that the optimum catalyst level for the best wrinkle recovery performance is approximately 5 to 6% solid zinc nitrate based on the weight of the resin solid. 5

Catalyst Level X Z I Based on Wrinkle Recovery Bath (Cataiyst,g.) (Water,g.) Resin Solids Value (W and F) l 9 158 2.0% 223 2 12 155 2.6% 221 3 i5 152 3.3% 251 4 18 149 4.0% 255 5 21 146 4.6% 258 6 24 143 5.3% 263 7 27 140 6.0% 284 8 30 137 6.6% 281" Unfinished Cotton Fabric Control 170 EXAMPLE 47 Polyester/ Cotton Cotton Wrinkle Recovery (Degrees) Fabric Fabric Warp 125 146 Filling 125 131 Total 250 277 Ravel Strip Tensile Strength (Pounds) ASTM Dl682-641R Warp 57.8 116.7 Filling 24.9 52.5 Elmendorf Tear (g.)

Warp 1200 3200 Filling 800 1600 Differential Wear (AATCC 119-1967T) 1200 Cycles 4.0+

thus finished resins indicate that the optimum curing temperature is 330F. for about 60 to seconds. An unfinished cotton control fabric has a value (W and F) of 213.

Curing Wrinkle Recovery Values of Samples Cured At:

Time 320F. 3 30F. 340F. 350F. 380F.

4 min. 298 303 312 305 314 3 min. 298 304 300 304 305 2 min. 295 307 304 309 305 90 sec. 290 296 296 303 307 60 sec. 284 300 301 301 309 30 sec. 288 298 305 EXAMPLE 48 A pad bath containing 8823 g. of a 34% solids solution of the resin prepared in Example 3 (the pH of which was adjusted to 5.5 with dilute HCl), 1600 g. of a zinc nitrate solution, 40 g. of a non-ionic Wetting agent, and 11,537 g. of water is prepared. A blanket containing a portion of 100% rayon fabric, 100% cotton fabric and a fabric portion of 50/50 poly(ethylene terephthalate)-cotton fibers is padded through the bath at 110F. to obtain a wet-pick-up of 70% based on the weight of the fabric. The fabrics are dried on a tenter frame at 220F. and then cured at 330F. for 90 seconds. The fabrics are evaluated for wrinkle recovery and washed appearance (AATCC Standard Test method 88A-l964 III-C-2). The results, set forth below, of those tests establish that our novel resins improve the washed appearance of fabrics treated therewith. The novel resins also produce a desirable, fimi hand to the cotton-polyester blend fabric.

Wrinkle Stoll Flex Recovery Abrasion Cycles Cotton Sample Value Warp Filling Unfinished Control 194 639 647 Treated 284 249 328 Unfinished Control With 194 726 465 Polyethylene Softener Treated With Polyethylene 291 518 627 Softener EXAMPLE A 100% cotton fabric'is padded wet-pick-up) at 120F. in a bath containing 135 g. of a 50% solids solution of the resin prepared in'Example 1.3, 24 g. ofa 10% zinc nitrate solution, 0.6 g. of-a non-ionic wetting agent and 141 g. water, The treated fabric :is dried at 220F. and cured at 330F. for seconds. Thefinished fabric is tested for wrinkle recoverye, tensile strength. and abrasion resistance. The results of ,those tests are;

Wrinkle Recovery Washed Appearance Ratings 1 Fabric Value l Wash 3 Washes 5 Washes I Unfinished Cotton 194 1.0 1.0 1.0 Resin-Finished Cotton 284 3.0 3.2 3.2 Unfinished Rayon 247 2.0 2.0 2.0 Resin-Finished Rayon 273 2.5 2.5 2.5 Unfinished Cotton- 3.0 3.0 3.0 polyester blend 7 Resin-Finished Cotton- 4.5 4.5 4.0 polyester blend Wrinkle Ravel Strip Recovery (Pounds) Stoll Flex (Cycles) Cotton Fabric Value Filling. Warp v Filling Unfinished Control 197 50 41 2616 2012 Resin-Finished 283 42 I 22 817 1021 EXAMPLE 49 EXAMPLES 51 through 53 A cotton fabric is finished by the method described in Example 48 and tested, according to standard methods, for wrinkle recovery, tensile strength and abrasion resistance. The test results given below show that cellulosic textile materials treated with one of our novel compositions possess excellent tensile strength and abrasion resistance properties.

According to the general procedure described in Example 47, samples of 100% cotton fabric are finished with (l) the N-methylol composition obtained by the procedure of Example 21, (2) the N-methylol "composition of Example 22, and (3) the N-methylol composition obtained in Example 23. The fabrics finished with each of those resins are evaluated for wrinkle recovery,

tensile strength and abrasion resistance. The test results Dcgmw are described in Table 111. Wrinkle Recovery Ravel Strip Stoll Flex EXAMPLE 54 Cotton (W and F (Pounds) Abrasion (Cycles) Fabric l'olal) Filling Warp Filling According to the procedure described in Example 5, P 30, thesolution ,of compounds prepared in Example 24 Untrmcd o 53 40 3065 15 applied to a cotton fabric. The fin shed fabric has a Control i v r o Bath 1 2x9 37 24 x23 63: kle reco e y value of 305 (W and F),,:vh1le the Bum 2 2780 BR 29 WW H22 unfinished cotton control has a value of 185 (W and Bath 3 284 30 31 369 428 F). 10

. -TABLE 111 Wrinkle I Ravel Strip (Pounds) V v Stoll Flex (Cycles) Example No. Cotton Fabric Recovery Value Warp Filling Warp Filling 51 Unfinished Control 177 51.5 40.0 2413 51 Resin Finished 266 38.0 26.2 395 52 Unfinished Control 140 50.0 38.9 1949 1950 52 Resin Finished 268 34.4 v 23.2 413 365 53 Unfinished Control 198 7 50.2 37.9 v 2234 53 Resin Finished 244 37.8 23.8 283 EXAMPLE 55 Fabrics. treated with the novel resins are used to fabri- According to the procedure described in Example 29, the solution of poly-N-methylol hexahydro-4-ethyl 5-methyll4,5-d-]pyrimidine-2,7-(1H,3H)dione and poly-N-methylol co-products prepared in Example 26 is applied to a cotton fabric. The finished fabric has a wrinkle recovery value of 284 (W and F while the unfinished cotton control has a value of 185 (W and F).

EXAMPLE 56 According to the procedure described in Example 30, the poly-N-methylol hexahydro-4-ethyl-5- methylpyrimido[4,5-d]pyrimidine-2,7-(1H,3H)dione and co-products prepared accordingto Example 26 is applied to cotton fabric. The finished fabric has a wrinkle recovery value of 287 (W and F), while the unfinished cotton control has a value of 185 (W and F.).

EXAMPLE 57 Three pad baths are prepared using the following ingredients:

Bath 1 i 150 g. of a 50% aqueous solution of dihydroxydimethylolethylene urea;

150 g. of a 50% solution of the products of Example 21; 70 g. of a zinc nitrate solution; 2 g. of a non-ionic wetting agent; and sufficient water to bring the volume of the bath to 1000 ml.

Bath 2 150 g. of a 50% aqueous solution of dihydroxydimethylolethylene urea; 100 g. of a 50% solution of the solid products of Example 21; 50 g. of a 10% zinc nitrate solution; 2 g. ofa non-ionic wetting agent; and sufficient water to bring the volume of the bath to 1000 ml. Bath 3 250 g. of a 50% solution of dihydroxydimethylolethylene urea; 50 g. of a 10% zinc nitrate solution; 2 g. ofa non-ionic wetting agent; and sufficient water to bring the volume of the bath to 1000 ml. Cotton fabrics are padded in one of the baths and dried and cured according to the procedure described in Example 27. The treated fabrics and a control fabric then are tested for wrinkle recovery, tensile strength and abrasion resistance. The values obtained are:

cate garments having desirable wrinkle resistance properties with improved tensile strength and abrasion resistance. The novel. resin treated fabrics are, also useful in areas othe'rthan wearing apparel, such as bet sheets, pillowcases, etc. The resins may also be used to stabilize fabrics (woven and knit goods), as a hand modified, for fabrics, and as a binder for pigments, flame retardants. etc. V

The invention has been described in considerable detail with particular reference to certain preferred embodiments thereof, but it will be understood that variations and modifications may be effected within the spirit and scopeof the invention as described hereinabove.

We claim: I

l. A composition produced by the process which comprises contacting formaldehyde at a pH of (a) 8 or more or (b) 0.5 to 5 and at a temperature of about 20 to about C with an intermediate condensate obtained by contacting a urea compound having the formula R --NHCONH with a saturated aldehyde having the formula R CHO wherein R is hydrogen or lower alkyl and R is methyl, ethyl, propyl, butyl or isobutyl at a pH of 4 or less at a temperature of about 0 to about C., the mole ratio of urea to aldehyde being about 1:1 to about 1:2 and the mole ratio of formaldehyde to the aldehyde being about 2:1 to about 1:2.

2. A composition, according to claim 1, produced by the process which comprises contacting formaldehyde at a pH of(a) 8 or more or (b) 0.5 to 5, in the presence of water or a lower alkanol ata temperature of about 20 to about 100C+with an intermediate condensate obtained by contacting urea with a saturated aldehyde having the formula R*C HO at a pH of4 or less in the presence of water or a:lower alkanol at a temperature of about 0 to about 150C., the mole ratio of urea to aldehyde being about 1:1 to about 1:2 andv the mole ratio of formaldehyde to the aldehyde being about 2:1

to about 1:2.-

3. A composition, according to claim 1, produced by the process'which comprises contacting formaldehyde at a pH of about 10 to about 12.5 in the presence of water and a base selected from the group consisting of sodium hydroxide, sodium carbonate, sodium bicarbonate, potassium hydroxide, potassium carbonate and potassium bicarbonate at a temperature of about 25 to about 55C. with an intermediate condensate obtained about 2 to about 3 and the mole ratio of formaldehyde to urea being about l.5:l to about 2.5: l.

4. A composition produced by the process defined in claim 3 wherein the acid is hydrochloric acid and the mole ratio of formaldehyde to urea is about 2:1. 

1. A COMPOSITION PRODUCED BY THE PROCESS WHICH COMPRISES CONTACTING FORMALDEHYDE AT A PH OF (A) 8 OR MORE OR (B) 0.5 TO 5 AND AT A TEMPERATURE OF ABOUT -20% TO ABOUT 100*C WITH AN INTERMEDIATE CONDENSATE OBTAINED BY CONTACTING A UREA COMPOUND HAVING THE FORMULA 4-NHCOHN2 WITH A SATURATED ALDEHYDE HAVING THE FORMULA R3-CHO WHEREIN RN IS HYDROGEN OR LOWER ALKYL AND R3 IS METHYL ETHYL PROPYL BETYL OR ISOBUTYL AT A PH OF 4 OR LESS AT A TEMPERATURE OF ABOUT 0* TO ABOUT 150*C THE MOLE RATIO OF UREA TO ALDEHYDE BEING ABOUT 1:1 TO ABOUT 1:2 AND THE MOLE RATIO OF FORMALDEHYDE TO THE ALDEHYDE BEING ABOUT 2:1 1:2.
 2. A composition, according to claim 1, produced by the process which comprises contacting formaldehyde at a pH of (a) 8 or more or (b) 0.5 to 5, in the presence of water or a lower alkanol at a temperature of about -20* to about 100*C. with an intermediate condensate obtained by contacting urea with a saturated aldehyde having the formula R3-CHO at a pH of 4 or less in the presence of water or a lower alkanol at a temperature of about 0* to about 150*C., the mole ratio of urea to aldehyde being about 1:1 to about 1:2 and the mole ratio of formaldehyde to the aldehyde being about 2:1 to about 1:2.
 3. A composition, according to claim 1, produced by the process which comprises contacting formaldehyde at a pH of about 10 to about 12.5 in the presence of water and a base selected from the group consisting of sodium hydroxide, sodium carbonate, sodium bicarbonate, potassium hydroxide, potassium carbonate and potassium bicarbonate at a temperature of about 25* to about 55*C. with an intermediate condensate obtained by contacting urea with acetaldehyde at a pH of about 0.5 to about 2 in the presence of water and an acid selected from the group consisting of hydrochloric acid and sulfuric acid at a temperature of about 30* to about 80*C., the mole ratio of urea to acetaldehyde bEing about 2 to about 3 and the mole ratio of formaldehyde to urea being about 1.5:1 to about 2.5:1.
 4. A composition produced by the process defined in claim 3 wherein the acid is hydrochloric acid and the mole ratio of formaldehyde to urea is about 2:1. 